Difference between revisions of "751.17 Concrete Slab Bridges"

751.17.1 General

This article illustrates the general design procedure for Continuous Concrete Slab Bridge using AASHTO LRFD Bridge Design Specifications.

751.17.1.1 Material Properties

Concrete:
Unit weight of reinforced concrete,		${\displaystyle \,{\boldsymbol {\gamma }}_{c}=0.150kcf}$
Continuous Cast-In-Place Solid/Voided Concrete Slab
	Class B-2	${\displaystyle \,f'_{c}=4.0ksi}$
		${\displaystyle \,n=8}$
Precast Prestressed Multicell Voided Concrete Girders
	Class A-1	${\displaystyle f'_{c}=6.0ksi}$
		${\displaystyle f'_{ci}=4.5ksi}$
		${\displaystyle n=8}$
Intermediate bent columns, end bents (below construction joint at bottom of slab) in continuous concrete slab bridges
	Class B-1	${\displaystyle f'_{c}=4.0ksi}$
		${\displaystyle n=8}$
	Class B, Open bent, footing	${\displaystyle f'_{c}=3.0ksi}$
		${\displaystyle n=10}$
Modulus of elasticity, ${\displaystyle E_{c}=33,000\ K_{1}\ (w_{c}^{1.5}){\sqrt {f_{c}^{'}}}}$
	Where:
	f'c in ksi
	wc = unit weight of nonreinforced concrete = 0.145 kcf
	K1 = correction factor for source of aggregate
	---- = 1.0 unless determined by physical testing
Modulus of rupture, ${\displaystyle f_{r}}$ = 0.24 ${\displaystyle {\sqrt {f_{c}^{'}}}}$     LRFD 5.4.2.6
	Where:
	f'c in ksi
Reinforcing steel:
	Minimum yield strength,	${\displaystyle \,f_{y}=60.0ksi}$
	Steel modulus of elasticity	${\displaystyle \,E_{s}=29000ksi}$
Unit weight of future wearing surface,		${\displaystyle \,{\boldsymbol {\gamma }}_{fws}=140lb./ft^{3}}$

751.17.2 Design

751.17.2.1 Limit States and Load Factors

In general, each component shall satisfy the following equation:

${\displaystyle Q=\textstyle \sum \eta _{i}\gamma _{i}Q_{i}\leq \phi R_{n}=R_{r}}$

Where:

${\displaystyle Q}$	= Total factored force effect
${\displaystyle Q_{i}}$	= Force effect
${\displaystyle \eta _{i}}$	= Load modifier
${\displaystyle \gamma _{i}}$	= Load factor
${\displaystyle \phi }$	= Resistance factor
${\displaystyle R_{n}}$	= Nominal resistance
${\displaystyle R_{r}}$	= Factored resistance

Limit States

The following limit states shall be considered for slab and edge beam design:

STRENGTH - I

SERVICE - I

FATIGUE

EXTREME EVENT - II

Resistance factors

For STRENGTH limit state,

Flexure and tension of reinforced concrete, ${\displaystyle \phi }$ = 0.90

Shear and torsion, ${\displaystyle \phi }$ = 0.90

For all other limit states, ${\displaystyle \phi }$ = 1.00

Load Modifiers

751.17.2.2 Loads

Permanent (Dead) Loads

Permanent loads include the following:

Slab weight

Future Wearing Surface

A 3” thick future wearing surface (35psf) shall be considered on the roadway.

Barrier/Railing

For slab overhang design, assume the weight of the barrier or railing acts at the centroid of the barrier or railing.

Gravity Live Loads

Gravity live loads include vehicular, dynamic load allowance, and pedestrian loads.

Vehicular

The design vehicular live load HL-93 shall be used. It consists of either the design truck or a combination of design truck and design lane load.

For slab design, where the primary strips are longitudinal, the force effects shall be determined on the following basis:

• The longitudinal strips shall be designed for all loads specified in AASHTO Article 3.6.1.3.3 includuing lane load.

• For the purpose of slab design, the lane load consists of a load equal to 0.640 klf uniformly distributed over 10 feet in the transverse direction.

For precast prestressed multicell girders, live load shall be distributed according to AASHTO LRFD Tables 4.6.2.2.2b-1, 4.6.2.2.2d-1, 4.6.2.2.3a-1 and 4.6.2.2.3b-1 for both moment and shear.

Dynamic Load Allowance

The dynamic load allowance replaces the effect of impact used in AASHTO Standard Specifications. It accounts for wheel load impact from moving vehicles. For slabs, the static effect of the vehicle live load shall be increased by the percentage specified in Table below.

Dynamic Load Allowance, ${\displaystyle IM}$

Slab Component	${\displaystyle IM}$
Deck Joints – All Limit States	75%
All Other Limit States	33%

The factor to be applied to the static load shall be taken as:

${\displaystyle \,(1+IM)}$

The dynamic load allowance is not to be applied to pedestrian or design lane loads.

Multiple Presence Factor, ${\displaystyle \,m}$:

The multiple presence factor accounts for the probability for multiple trucks passing over a multilane bridge simultaneously.

${\displaystyle \,m}$ =	1.20 for 1 Loaded Lane
	1.00 for 2 Loaded Lanes
	0.85 for 3 Loaded Lanes
	0.65 for more than 3 Loaded Lanes

Pedestrian

Pedestrian live load on sidewalks greater than 2 ft wide shall be:

${\displaystyle \,PL}$ =

0.075 ksf

This does not include bridges designed exclusively for pedestrians or bicycles.

For Additional Design Information, see LRFD 5.14.4.2

751.17.3 Details

751.17.3.1 Solid Slabs

SLAB LONGITUDINAL SECTIONS - SOLID SLABS

Note:

All longitudinal dimensions shown are horizontal.

751.17.3.2 C.I.P. Voided Slabs

SLAB LONGITUDINAL SECTIONS - CAST-IN-PLACE VOIDED SLAB

(*) 3'-0" or greater than or equal to 5% of span length.

(**) By Design (6" increments measured normal to the centerline of bent) (The minimum is

equal to the column diameter + 2'6")

Note:

All longitudinal dimensions shown are horizontal (Bridges on grades and vertical curves, included).

For sections A-A and B-B, see below.

SLAB CROSS SECTION

Sonovoids are produced in half sizes 2" to 18". D = 4" to 36"   T=19" (Min. preferred. Consult Structural Project Manager prior to the use of a thinner slab.)

Notes:
(*)   Increase the Dimension "T" by 1/2" for #14 bars placed in the top or bottom of the slab.

Increase the Dimension "T" by 1" for #14 bars placed in the top and bottom of the slab.

("T" and "D" are based on 3" clearance which includes the integral wearing surface to the top of the longitudinal bar.)

(**)  For Roadway with slab drains, use 10" minimum. For Roadways that require additional reinforcement for resisting moment of the edge beam 20" minimum. Check for adequate space for development of barrier or railing reinforcement.